Add to ORKGDislocations in ceramic oxides are drawing increasing attention thanks to their promising properties, such as dislocation-tuned electrical conductivity, thermal conductivity, and electro-mechanical properties. However, due to the brittleness of most oxides at room temperature, it remains a great challenge to engineer dislocations without forming cracks, which is a prerequisite for harnessing the functionalities. From the aspect of mechanical deformation, nano-/micromechanical testing has been found to be a feasible approach to achieve this goal. Please click Download on the upper right corner to see the full abstract
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocations have been identified to modify both the functional and mechanical properties of some ce...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Dislocation-based functionalities in inorganic ceramics and semiconductors are drawing increasing at...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...
Most oxide ceramics are known to be brittle macroscopically at room temperature with little or no di...